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An FPGA implementation of neutrino track detection for the IceCube telescopeWernhoff, Carl January 2010 (has links)
<p>The <em>IceCube telescope</em> is built within the ice at the geographical South Pole in the middle of the Antarctica continent. The purpose of the telescope is to detect muon neutrinos, the muon neutrino being an elementary particle with minuscule mass coming from space.</p><p>The detector consists of some 5000 DOMs registering photon hits (light). A muon neutrino traveling through the detector might give rise to a track of photons making up a straight line, and by analyzing the hit output of the DOMs, looking for tracks, neutrinos and their direction can be detected.</p><p>When processing the output, triggers are used. Triggers are calculation- efficient algorithms used to tell if the hits seem to make up a track - if that is the case, all hits are processed more carefully to find the direction and other properties of the track.</p><p>The Track Engine is an additional trigger, specialized to trigger on low- energy events (few track hits), which are particularly difficult to detect. Low-energy events are of special interest in the search for Dark Matter.</p><p>An algorithm for triggering on low-energy events has been suggested. Its main idea is to divide time in overlapping time windows, find all possible pairs of hits in each time window, calculate the spherical coordinates θ and ϕ of the position vectors of the hits of the pairs, histogram the angles, and look for peaks in the resulting 2d-histogram. Such peaks would indicate a straight line of hits, and, hence, a track.</p><p>It is not believed that a software implementation of the algorithm would be fast enough. The Master's Thesis project has had the aim of developing an FPGA implementation of the algorithm.</p><p>Such an FPGA implementation has been developed. Extensive tests on the design has yielded positive results showing that it is fully functional. The design can be synthesized to about 180 MHz, making it possible to handle an incoming hit rate of about 6 MHz, giving a margin of more than twice to the expected average hit rate of 2.6 MHz.</p>
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A Search for Dark Matter in the Sun with AMANDA and IceCubeEngdegård, Olle January 2011 (has links)
A search for weakly interacting massive particles (WIMPs) annihilating in the Sun was performed with the IceCube and AMANDA neutrino telescopes, using data from 2008 corresponding to 149 days of livetime. Assuming that particles in the dark matter halo scatter and accumulate in the centre of the Sun, Majorana WIMPs may pair-wise annihilate and give rise to a neutrino signal detectable in an experiment at Earth. No excess of muon-neutrinos from the Sun was observed, and limits on the νμ-flux were set for masses between 50 GeV and 5 TeV considering WIMPs annihilating into b‾b and W+W-. Separate limits were also calculated for the case of the lightest Kaluza-Klein particle. The flux limits were converted to limits on the spin-dependent and spin-independent WIMP-proton cross sections, σSD and σSI. The search was combined using a joint likelihood method with AMANDA and IceCube data from 2001-2007, yielding the 90% CL upper limits Φμ < 103 km-2y-1 for a WIMP mass of 1000 GeV and σSD < 1.28×10-4 pb for 250 GeV, both for the W+W- spectrum. / IceCube
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Search for low mass WIMPs with the AMANDA neutrino telescopeDavour, Anna January 2007 (has links)
Recent measurements show that dark matter makes up at least one fifth of the total energy density of the Universe. The nature of the dark matter is one of the biggest mysteries in current particle physics and cosmology. Big Bang nucleosynthesis limits the amount of baryonic matter that can exist, and shows that the dark matter has to be non-baryonic. Particle physics provides some candidates for non-baryonic matter that could solve the dark-matter problem, weakly interacting massive particles (WIMPs) being the most popular. If these particles were created in the early Universe a substatial relic abundance would exist today. WIMPs in our galactic halo could be gravitationally bound in the Solar System and accumulate inside heavy bodies like the Earth. Supersymmetric extensions to the Standard Model give a viable WIMP dark matter candidate in the form of the lightest neutralino. This thesis describes an indirect search for WIMPs by the neutrino signature from neutralino annihilation at the core of the Earth using the AMANDA detector. As opposed to previous dark matter searches with AMANDA, this work focuses on the hypothesis of a relatively light WIMP particle with mass of 50-250GeV/c2 The AMANDA neutrino telescope is an array of photomultiplier tubes installed in the clear glacier ice at the South Pole which is used as Cherenkov medium. Data taken with AMANDA during the period 2001-2003 is analyzed. The energy threshold of the detector is lowered by the use of a local correlation trigger, and the analysis is taylored to select vertically upgoing low energy events. No excess above the expected atmospheric neutrino background is found. New limits on the flux of muons from WIMP annihilations in the center of the Earth are calculated.
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A Search for Solar Neutralino Dark Matter with the AMANDA-II Neutrino TelescopeBurgess, Thomas January 2008 (has links)
A relic density of Weakly Interacting Massive Particles (WIMPs) remaining from the Big Bang constitutes a promising solution to the Dark Matter problem. It is possible for such WIMPs to be trapped by and accumulate in gravitational potentials of massive dense objects such as the Sun. A perfect WIMP candidate appears in certain supersymmetric extensions to the Standard Model of particle physics, where the lightest supersymmetric particle is a neutralino which can be stable, massive and weakly interacting. The neutralinos may annihilate pair-wise and in these interactions neutrinos with energies ranging up to the neutralino mass can be indirectly produced. Hence, a possible population of dark matter neutralinos trapped in the Sun can give rise to an observable neutrino flux. The Antarctic Muon And Neutrino Detector Array, AMANDA, is a neutrino telescope that detects Cherenkov light emitted by charged particles created in neutrino interactions in the South Pole glacial ice sheet using an array of light detectors frozen into the deep ice. In this work data taken with the AMANDA-II detector during 2003 are analyzed to measure or put upper bounds on the flux of such neutrinos from the Sun. In the analysis detailed signal and background simulations are compared to measurements. Background rejection filters optimized for various neutralino models have been constructed. No excess above the background expected from neutrinos and muons created in cosmic ray interactions in the atmosphere was found. Instead 90% confidence upper limits have been set on the neutralino annihilation rate in the Sun and the muon flux induced by neutralino signal neutrinos.
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Development of a particle flux detection system for the MERIT high intensity target experiment at CERNPalm, Marcus January 2008 (has links)
The construction of a high intensity neutrino source requires multi megawatt beams and challenges the targets in use. MERIT is a proof-of-principle test for a novel kind of neutrino factory target, employing a 24 GeV/c proton beam and a 1 cm in diameter free mercury jet as beam target. This thesis describes the design and implementation of a secondary particle flux production detection system. Employed detectors are polycrystalline diamond detectors and electron multipliers. Simulations of the secondary particle production have been made using FLUKA. The detection system is remotely controlled by a LabView interface and experimental observations from the initial analysis are presented.
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Analyse des données de l'expérience NEMO3 pour la recherche de la désintégration double bêta sans émission de neutrinos. Étude des biais systématiques du calorimètre et développements d'outils d'analyseHugon, Christophe 29 November 2012 (has links) (PDF)
L'expérience NEMO3 était dédiée à la recherche de la désintégration ββ0ν à l'aide de diverses sources d'isotopes de désintégration double bêta (principalement ¹ººMo, ⁸²Se, ¹¹⁶Cd et ¹³ºTe pour un total d'environ 10 kg). Le détecteur était localisé dans le Laboratoire souterrain de Modane, à mi-parcours du tunnel du Fréjus. Cette expérience a permis de démontrer que la technologie "tracko-calo" est très compétitive et a de plus offert de nouveaux résultats pour la recherche des désintégrations ββ2ν et ββ0ν. Par ailleurs, elle a ouvert la voie pour son successeur SuperNEMO, dont le but est d'atteindre 100 kg de ⁸²Se (pour une sensibilité de 10²⁶ années). Le but principal de cette thèse a été de mesurer le temps de demi-vie des désintégrations ββ2ν et ββ0ν du ¹ººMo vers les états excités 0₁⁺ du ¹ººRu à l'aide des données totales de NEMO3, avec de nouvelles méthodes d'analyse et un développement du programme d'analyse de la collaboration. Les résultats obtenus pour la désintégration ββ2ν du ¹ººMo vers l'état fondamental (gs) et excité (0₁⁺) du ¹ººRu sont T1/2(ββ2ν,gs)=(7,05±0,01(stat)±0,54(syst)).10¹⁸ ans et T1/2(ββ2ν,0₁⁺)=(6,15±1,1(stat)±0,78)).10²º ans. Ces résultats sont compatibles avec les résultats publiés par la collaboration. Quant à la désintégration ββ0ν(0₁⁺), ce travail permet d'obtenir un temps de demi-vie de T1/2(ββ0ν, 0₁⁺)>2,6.10²³ ans, améliorant significativement les derniers résultats publiés. De plus ces méthodes ont aussi permis de présenter un nouveau modèle de bruit de fond de l'expérience, plus exhaustif. Le second but de ce travail a été de mesurer les erreurs systématiques du calorimètre de NEMO3 dues, entre autres, à la longueur d'onde des systèmes d'étalonnage du détecteur. Ce travail a été réalisé notamment à l'aide d'un banc de test basé sur des DEL. Ce banc a aussi permis de contribuer au développement du calorimètre de SuperNEMO, particulièrement au travers de mesures de linéarité et de caractéristiques temporelles des PM destinés au démonstrateur de l'expérience.
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An FPGA implementation of neutrino track detection for the IceCube telescopeWernhoff, Carl January 2010 (has links)
The IceCube telescope is built within the ice at the geographical South Pole in the middle of the Antarctica continent. The purpose of the telescope is to detect muon neutrinos, the muon neutrino being an elementary particle with minuscule mass coming from space. The detector consists of some 5000 DOMs registering photon hits (light). A muon neutrino traveling through the detector might give rise to a track of photons making up a straight line, and by analyzing the hit output of the DOMs, looking for tracks, neutrinos and their direction can be detected. When processing the output, triggers are used. Triggers are calculation- efficient algorithms used to tell if the hits seem to make up a track - if that is the case, all hits are processed more carefully to find the direction and other properties of the track. The Track Engine is an additional trigger, specialized to trigger on low- energy events (few track hits), which are particularly difficult to detect. Low-energy events are of special interest in the search for Dark Matter. An algorithm for triggering on low-energy events has been suggested. Its main idea is to divide time in overlapping time windows, find all possible pairs of hits in each time window, calculate the spherical coordinates θ and ϕ of the position vectors of the hits of the pairs, histogram the angles, and look for peaks in the resulting 2d-histogram. Such peaks would indicate a straight line of hits, and, hence, a track. It is not believed that a software implementation of the algorithm would be fast enough. The Master's Thesis project has had the aim of developing an FPGA implementation of the algorithm. Such an FPGA implementation has been developed. Extensive tests on the design has yielded positive results showing that it is fully functional. The design can be synthesized to about 180 MHz, making it possible to handle an incoming hit rate of about 6 MHz, giving a margin of more than twice to the expected average hit rate of 2.6 MHz.
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Study On Non Standard Interaction Of Neutrino And Unparticle Physics With Neutrino-electron Scattering Data At Low Energy In Texono ExperimentBilmis, Selcuk 01 October 2010 (has links) (PDF)
Neutrino-electron scatterings are purely leptonic processes with robust Standard Model (SM)
predictions. Their measurements can therefore provide constraints to physics beyond SM.
The &nu / e &minus / e&minus / data taken at the Kuo-Sheng Reactor Neutrino Laboratory were used to probe two sceneria: Non-Standard Neutrino Interactions (NSI) and Unparticle Physics. New constraints
were placed to the NSI parameters (&epsilon / eL , &epsilon / eR ), (&epsilon / eL , &epsilon / eR ) and (&epsilon / eL , &epsilon / eR ) , as well as to the coupling constants for scalar (&lambda / 0 ) and vector (&lambda / 1 ) unparticles to the neutrinos and electrons.
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High-speed Automatic Scanning System For Emulsion Analysis In The Opera ExperimentAltinok, Ozgur 01 July 2011 (has links) (PDF)
The aim of the OPERA experiment is to verify the neutrino oscillation, directly measuring
the appearance of from an initially pure beam produced at CERN. For this purpose
OPERA detector is located underground Gran Sasso Laboratory(LNGS) 730 km away from
CERN. The detector structure designed to be a hybrid system consisting of emulsion targets
and electronic detectors. Total area of the emulsion targets in the OPERA detector is around
110000 m2 which needs fast and reliable automatic scanning systems. For this purpose, two
dierent automatic scanning systems were developed in Japan and Europe. For now there
are 12 scanning laboratories dedicated to the OPERA Experiment. The Emulsion Scanning
Laboratory in the Physics department of METU is one of the scanning laboratories for the
OPERA Experiment. The automatic scanning system in METU is European type which is
using commercial hardware for easy construction and maintain. Also the laboratory has a
unique feature in terms of experimental high energy physics laboratories. The emulsion scan-
ning laboratory in METU is the
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Development of a particle flux detection system for the MERIT high intensity target experiment at CERNPalm, Marcus January 2008 (has links)
<p>The construction of a high intensity neutrino source requires multi megawatt beams and challenges the targets in use. MERIT is a proof-of-principle test for a novel kind of neutrino factory target, employing a 24 GeV/c proton beam and a 1 cm in diameter free mercury jet as beam target. This thesis describes the design and implementation of a secondary particle flux production detection system. Employed detectors are polycrystalline diamond detectors and electron multipliers. Simulations of the secondary particle production have been made using FLUKA. The detection system is remotely controlled by a LabView interface and experimental observations from the initial analysis are presented.</p>
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